2,220 research outputs found
Ultrafast QND measurements based on diamond-shape artificial atom
We propose a Quantum Non Demolition (QND) read-out scheme for a
superconducting artificial atom coupled to a resonator in a circuit QED
architecture, for which we estimate a very high measurement fidelity without
Purcell effect limitations. The device consists of two transmons coupled by a
large inductance, giving rise to a diamond-shape artificial atom with a logical
qubit and an ancilla qubit interacting through a cross-Kerr like term. The
ancilla is strongly coupled to a transmission line resonator. Depending on the
qubit state, the ancilla is resonantly or dispersively coupled to the
resonator, leading to a large contrast in the transmitted microwave signal
amplitude. This original method can be implemented with state of the art
Josephson parametric amplifier, leading to QND measurements in a few tens of
nanoseconds with fidelity as large as 99.9 %.Comment: 5 pages, 4 figure
Quantum dynamics of a dc-SQUID coupled to an asymmetric Cooper pair transistor
We present a theoretical analysis of the quantum dynamics of a
superconducting circuit based on a highly asymmetric Cooper pair transistor
(ACPT) in parallel to a dc-SQUID. Starting from the full Hamiltonian we show
that the circuit can be modeled as a charge qubit (ACPT) coupled to an
anharmonic oscillator (dc-SQUID). Depending on the anharmonicity of the SQUID,
the Hamiltonian can be reduced either to one that describes two coupled qubits
or to the Jaynes-Cummings Hamiltonian. Here the dc-SQUID can be viewed as a
tunable micron-size resonator. The coupling term, which is a combination of a
capacitive and a Josephson coupling between the two qubits, can be tuned from
the very strong- to the zero-coupling regimes. It describes very precisely the
tunable coupling strength measured in this circuit and explains the
'quantronium' as well as the adiabatic quantum transfer read-out.Comment: 20 page
Decoherence processes in a current biased dc SQUID
A current bias dc SQUID behaves as an anharmonic quantum oscillator
controlled by a bias current and an applied magnetic flux. We consider here its
two level limit consisting of the two lower energy states | 0 \right> and |
1 \right>. We have measured energy relaxation times and microwave absorption
for different bias currents and fluxes in the low microwave power limit.
Decoherence times are extracted. The low frequency flux and current noise have
been measured independently by analyzing the probability of current switching
from the superconducting to the finite voltage state, as a function of applied
flux. The high frequency part of the current noise is derived from the
electromagnetic environment of the circuit. The decoherence of this quantum
circuit can be fully accounted by these current and flux noise sources.Comment: 4 pages, 4 figure
Machine Learning Classification of SDSS Transient Survey Images
We show that multiple machine learning algorithms can match human performance
in classifying transient imaging data from the Sloan Digital Sky Survey (SDSS)
supernova survey into real objects and artefacts. This is a first step in any
transient science pipeline and is currently still done by humans, but future
surveys such as the Large Synoptic Survey Telescope (LSST) will necessitate
fully machine-enabled solutions. Using features trained from eigenimage
analysis (principal component analysis, PCA) of single-epoch g, r and
i-difference images, we can reach a completeness (recall) of 96 per cent, while
only incorrectly classifying at most 18 per cent of artefacts as real objects,
corresponding to a precision (purity) of 84 per cent. In general, random
forests performed best, followed by the k-nearest neighbour and the SkyNet
artificial neural net algorithms, compared to other methods such as na\"ive
Bayes and kernel support vector machine. Our results show that PCA-based
machine learning can match human success levels and can naturally be extended
by including multiple epochs of data, transient colours and host galaxy
information which should allow for significant further improvements, especially
at low signal-to-noise.Comment: 14 pages, 8 figures. In this version extremely minor adjustments to
the paper were made - e.g. Figure 5 is now easier to view in greyscal
Dynamical Behavior of a Squid Ring Coupled to a Quantized Electromagnetic Field
In this paper we investigate the dynamical behavior of a SQUID ring coupled
to a quantized single-mode electromagnetic field. We have calculated the
eigenstates of the combined fully quantum mechanical SQUID-field system.
Interesting phenomena occur when the energy difference between the usual
symmetric and anti-symmetric SQUID states equals the field energy . We find the
low-energy lying entangled stationary states of the system and demonstrate that
its dynamics is dominated by coherent Rabi oscillations.Comment: 6 pages, 2 figures. to be published on International Journal of
Modern Physics
Nanosecond quantum state detection in a current biased dc SQUID
This article presents our procedure to measure the quantum state of a dc
SQUID within a few nanoseconds, using an adiabatic dc flux pulse. Detection of
the ground state is governed by standard macroscopic quantum theory (MQT), with
a small correction due to residual noise in the bias current. In the two level
limit, where the SQUID constitutes a phase qubit, an observed contrast of 0.54
indicates a significant loss in contrast compared to the MQT prediction. It is
attributed to spurious depolarization (loss of excited state occupancy) during
the leading edge of the adiabatic flux measurement pulse. We give a simple
phenomenological relaxation model which is able to predict the observed
contrast of multilevel Rabi oscillations for various microwave amplitudes.Comment: 10 pages, 8 figure
On the generation of multipartite entangled states in Josephson architectures
We propose and analyze a scheme for the generation of multipartite entangled
states in a system of inductively coupled Josephson flux qubits. The qubits
have fixed eigenfrequencies during the whole process in order to minimize
decoherence effects and their inductive coupling can be turned on and off at
will by tuning an external control flux. Within this framework, we will show
that a W state in a system of three or more qubits can be generated by
exploiting the sequential one by one coupling of the qubits with one of them
playing the role of an entanglement mediator.Comment: 10 pages, 3 figure
Coherent oscillations in a superconducting multi-level quantum system
We have observed coherent time evolution of states in a multi-level quantum
system, formed by a current-biased dc SQUID. The manipulation of the quantum
states is achieved by resonant microwave pulses of flux. The number of quantum
states participating in the coherent oscillations increases with increasing
microwave power. Quantum measurement is performed by a nanosecond flux pulse
which projects the final state onto one of two different voltage states of the
dc SQUID, which can be read out
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